diseño sismico de conec.pdf
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Program
toR
educetheEarthqua
keHazardsof
Steel
MomentFrameStru
ctures
FEDERAL EMERGENCY MANAGEMENT AGENCY FEMA XXX/January, 1999
Seismic Design Criteria
for New Moment-Resisting
Steel Frame Construction
50%
DRAF
T
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Working Draft
This document has been produced as a preliminary working draft as part of theSAC Joint Ventures project to develop practice guidelines for design, evaluation,repair, and retrofit of moment-resisting steel frame structures. The purpose ofthis draft is to permit the project development team and prospective users of theguidelines to explore the basic data requirements and alternative methods ofpresenting this data in an eventual series of guideline documents. Althoughportions of the document must necessarily appear in the form of an actualguideline, it is not intended to serve as an interim guideline document.Information contained in this document is incomplete and in some cases, isknown to be erroneous or otherwise incorrect. Information presented hereinshould not be used as the basis for engineering projects and decisions, norshould it be disseminated or attributed.
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THE SAC JOINT VENTURE
SAC is a joint venture of the Structural Engineers Association of California (SEAOC), the
Applied Technology Council (ATC), and California Universities for Research in Earthquake
Engineering (CUREe), formed specifically to address both immediate and long-term needs related
to solving performance problems with welded steel moment frame connections discoveredfollowing the 1994 Northridge earthquake. SEAOC is a professional organization composed of
more than 3,000 practicing structural engineers in California. The volunteer efforts of SEAOCs
members on various technical committees have been instrumental in the development of the
earthquake design provisions contained in the Uniform Building Codeas well as theNational
Earthquake Hazards Reduction Program (NEHRP) Provisions for Seismic Regulations for New
Buildings and other Structures (NEHRP Provisions). The Applied Technology Council is a non-
profit organization founded specifically to perform problem-focused research related to structural
engineering and to bridge the gap between civil engineering research and engineering practice. It
has developed a number of publications of national significance including ATC 3-06, which serves
as the basis for theNEHRP Provisions. CUREe is a nonprofit organization formed to promote and
conduct research and educational activities related to earthquake hazard mitigation. CUREes eight
institutional members are: the California Institute of Technology, Stanford University, the
University of California at Berkeley, the University of California at Davis, the University of
California at Irvine, the University of California at Los Angeles, the University of California at San
Diego, and the University of Southern California. This collection of university earthquake research
laboratory, library, computer and faculty resources is among the most extensive in the United
States. The SAC Joint Venture allows these three organizations to combine their extensive and
unique resources, augmented by subcontractor universities and organizations from around the
nation, into an integrated team of practitioners and researchers, uniquely qualified to solve
problems related to the seismic performance of steel moment frame structures.
DISCLAIMER
The purpose of this document is to provide practicing engineers and building officials with a
resource document for the design of moment-resisting steel frame structures to resist the effects of
earthquakes. The recommendations were developed by practicing engineers based on professional
judgment and experience and a program of laboratory, field and analytical research. No warranty
is offered with regard to the recommendations contained herein, either by the Federal
Emergency Management Agency, the SAC Joint Venture, the individual joint venture
partners, their directors, members or employees. These organizations and their employees do
not assume any legal liability or responsibility for the accuracy, completeness, or usefulness of
any of the information, products or processes included in this publication. The reader iscautioned to carefully review the material presented herein and exercise independent
judgment as to its suitability for application to specific engineering projects. These guidelines
have been prepared by the SAC Joint Venture with funding provided by the Federal Emergency
Management Agency, under contract number EMW-95-C-4770.
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TABLE OF CONTENTS
1. Introduction1.1. Purpose1.2. Intent
1.3. Background1.4. Application1.5. The SAC Joint Venture1.6. Sponsors1.7. Guidelines and Overview
2. General Requirements2.1. Scope2.2. Applicable Codes and Standards2.3. Design Performance Objectives2.4. System Selection
2.4.1. Configuration and Load Path2.4.2. Selection of Moment Frame Type2.4.3. Connection Type2.4.4. Redundancy
2.5. Structural Materials2.5.1. Material Specifications2.5.2. Material Strength Properties
2.6. Structural Analysis2.7. Mathematical Modeling
2.7.1. Basic Assumptions2.7.2. Frame Configuration
2.7.3. Horizontal Torsion2.7.4. Foundation Modeling2.7.5. Diaphragms2.7.6. P-Delta Effects
2.7.6.1.Static P-Effects2.7.6.2.Dynamic P-Effects
2.7.7. Multi-direction Excitation Effects2.7.8. Verification of Analysis Assumptions
2.8. Frame Design2.8.1. Strength of Beams and Columns
2.8.2. Panel zone Strength2.8.3. Connection Strength and Degradation2.8.4. P-Delta Effects2.8.5. Section Compactness Requirements
2.9. Connection Design2.10. Specifications2.11. Quality Assurance and Control2.12. Other Structural Systems
2.12.1.Column Splices
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2.12.2.Column Bases
3. Connection Qualification3.1. Scope3.2. Basic Design Approach
3.2.1. Frame Configuration3.2.2. Inter-Story Drift Capacity3.2.3. Connection Configuration3.2.4. Determine Plastic Hinge Locations3.2.5. Determine Probable Plastic Moment at Hinges3.2.6. Determine Shear at the Plastic Hinge3.2.7. Determine Strength Demands at Each Critical Section
3.3. General Requirements3.3.1. Beams
3.3.1.1.Beam Flange Stability3.3.1.2.Beam Depth Effects
3.3.1.3.Beam Flange Thickness Effects3.3.2. Welded Joints
3.3.2.1.Through-Thickness Strength3.3.2.2.Base Material Notch-Toughness3.3.2.3.Weld Wire Notch-Toughness3.3.2.4.Weld Wire Matching and Overmatching3.3.2.5.Weld Backing, Runoff Tabs, Reinforcing Fillet Welds3.3.2.6.Overlay Fillet Welds3.3.2.7.Weld-Access Hole: Size, Shape, Workmanship
3.3.3. Other Design Issues for Welded Connections3.3.3.1.Continuity Plates
3.3.3.2.Panel Zone Strength3.3.4. Bolted Joints
3.3.4.1.Existing Conditions3.3.4.2.Connection Upgrades
3.4. Pre-qualified Welded FR Connections3.4.1. Welded Unreinforced Flange
3.4.1.1.Procedure for Sizing Shear Tabs3.4.1.2.Procedure for Weld Sizing
3.4.2. Welded Cover Plated Flanges (WCPF)3.4.3. Welded Flange Plates (WFP)3.4.4. Reduced Beam Section (RBS, or Dog Bone)
3.4.4.1.Procedure for Sizing Section Reduction3.4.4.2.Procedure for Sizing Shear Tabs3.4.4.3.Procedure for Flange Weld Sizing3.4.4.4.Fabrication Requirements3.4.4.5.Supplemental Lateral Bracing at RBS
3.4.5. Welded Single Haunch (WSH)3.4.6. Welded Double Haunch (WDH)3.4.7. Side Plate (SP)
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3.4.8. Slotted Web (SW)3.5. Pre-qualified Bolted FR Connections
3.5.1. Bolted End Plate3.5.2. Welded Flange Plates with Bolted Beam (WFPBB)
3.5.2.1.General Design Procedure
3.5.2.2.Bolt Shear3.5.2.3.Flange Plate3.5.2.4.Beam Flange3.5.2.5.Groove Weld3.5.2.6.Panel Zone
3.5.3. Bolted Bracket (BB)3.6. Pre-qualified PR Connections
3.6.1. Double Split Tee Connections (DST)3.6.1.1.Procedure for Sizing Tees3.6.1.2.Procedure for Sizing Bolts to Column Flange3.6.1.3.Procedure for Sizing Bolts to Beam Flange
3.6.2. Single Tee Composite (STC) Connection3.6.2.1.Procedure for Sizing Tees3.6.2.2.Procedure for Sizing Bolts to Column Flange3.6.2.3.Procedure for Sizing Bolts to Beam Flange3.6.2.4.Procedure for Sizing Shear Studs3.6.2.5.Procedure for Sizing Slab Reinforcement
3.6.3. Single Angle Composite (SAC)3.6.4. Shear Tab Composite (STC)
3.7. Non-pre-qualified Connections3.7.1. Testing Procedure3.7.2. Analytical Prediction of Behavior
3.7.3. Determination of Resistance Factor
4. Performance Evaluation4.1. Scope4.2. Performance Definition
4.2.1. Hazard Specification4.2.1.1.General4.2.1.2.Ground Shaking4.2.1.3.Other Hazards
4.2.2. Performance Levels4.2.2.1.Structural Performance Levels
4.2.2.1.1.Incipient Damage Performance Level (S-1)4.2.2.1.2.Collapse Prevent Performance Level (S-5)
4.2.2.2.Nonstructural Performance Levels4.2.2.2.1.Operational Performance Level (N-A)4.2.2.2.2.Immediate Occupancy Level (N-B)4.2.2.2.3.Life Safety Level (N-C)4.2.2.2.4.Hazards Reduced Level (N-D)
4.3. Evaluation Approach
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4.4. Analysis4.4.1. Alternative Procedures4.4.2. Procedure Selection4.4.3. Linear Static Procedure (LSP)
4.4.3.1.Basis of the Procedure
4.4.3.2.Modeling and Analysis Considerations4.4.3.3.Determination of Actions and Deformations
4.4.3.3.1.Pseudo Lateral Load4.4.3.3.2.Vertical Distribution of Seismic Forces4.4.3.3.3.Horizontal Distribution of Seismic Forces4.4.3.3.4.Floor Diaphragms4.4.3.3.5.Determination of Deformations4.4.3.3.6.Determination of Column Demands
4.4.4. Linear Dynamic Procedure (LDP)4.4.4.1.Basis of the Procedure4.4.4.2.Modeling and Analysis Considerations
4.4.4.2.1.General4.4.4.2.2.Ground Motion Characterization4.4.4.2.3.Response Spectrum Method4.4.4.2.4.Response-History Method
4.4.4.3.Determination of Actions and Deformations4.4.4.3.1.Factored Inter-Story Drift Demand4.4.4.3.2.Determination of Column Demands
4.4.5. Nonlinear Static Procedure (NSP)4.4.5.1.Basis of the Procedure4.4.5.2.Modeling and Analysis Considerations
4.4.5.2.1.General
4.4.5.2.2.Control Node4.4.5.2.3.Lateral Load Patterns4.4.5.2.4.Period Determination4.4.5.2.5.Analysis of Three-Dimensional Models4.4.5.2.6.Analysis of Two-Dimensional Models
4.4.5.3.Determination of Actions and Deformations4.4.5.3.1.Target Displacement4.4.5.3.2.Floor Diaphragms4.4.5.3.3.Factored Inter-Story Drift Demand4.4.5.3.4.Factored Column and Column Splice Demands
4.4.6. Nonlinear Dynamic Procedure (NDP)4.4.6.1.Basis of the Procedure4.4.6.2.Modeling and Analysis Considerations
4.4.6.2.1.General4.4.6.2.2.Ground Motion Characterization4.4.6.2.3.Response Spectrum Method4.4.6.2.4.Response-History Method
4.4.6.3.Determination of Actions and Deformations4.4.6.3.1.Modification of Demands
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4.4.6.3.2.Factored Inter-Story Drift Demand4.4.6.3.3.Factored Column and Column Splice Demands
4.5. Acceptance Criteria4.5.1. Inter-Story Drift Capacity4.5.2. Column Compressive Capacity
4.5.3. Column Splice Capacity4.6. Detailed Procedure for Determination of Performance Confidence
4.6.1. Hazard Paramaters4.6.2. Ground Motion Accellerograms4.6.3. Dynamic Pushover Analysis4.6.4. Determination of Factored Inter-story Drift Capacity4.6.5. Determination of Confidence Level
5. Materials and Fracture Resistant Design5.1. Scope5.2. Parent Materials
5.2.1. Steels5.2.2. Chemistry5.2.3. Tensile/Elongation Properties5.2.4. Toughness Properties5.2.5. Lamellar Discontinuities
5.3. Welding5.3.1. Welding Process5.3.2. Welding Procedures5.3.3. Welding Filler Metals5.3.4. Preheat and Interpass Temperatures5.3.5. Postheat
5.3.6. Controlled Cooling5.3.7. Metallurgical Stress Risers
5.4. Bolting5.5. Fracture Mechanics Principles
5.5.1. Introduction5.5.2. Crack Geometry5.5.3. Stress Variables5.5.4. Stress Intensity Factor5.5.5. Temperature5.5.6. Determining Notch Toughness5.5.7. Role of Notch Toughness5.5.8. Base Metal and Weld Metal Toughness
5.6. Connections Conducive to Brittle Fracture5.6.1. Loading Conditions5.6.2. Critical Connection Configurations
6. Structural Specifications6.1. Scope
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WORKING DRAFT - This document has been produced by the SAC Joint Venture for the purposes of preliminary
review and coordination between members of the project team. Information presented is known to be incomplete
and in some cases erroneous. This document should not be used for attribution, nor as the basis for engineering
decisions
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1. INTRODUCTION
1.1 Purpose
The purpose of this Seismic Design Criteria for Moment-Resisting Frame Construction is to
provide engineers and building officials with guidance for reliable earthquake-resistant design of
new structures incorporating moment-resisting steel frames. It is one of a series publications
prepared by the SAC Joint Venture addressing the issue of the seismic performance of moment-
resisting steel frame buildings. Companion publications include:
Post-earthquake Evaluation and Repair Criteria for Welded Steel Moment-Resisting Frame Construction- These guidelines provide recommendations
for: performing post-earthquake inspections to detect damage in steel frame
structures, evaluating the damaged structures to determine their safety in the
post-earthquake environment and repairing damaged structures.
Seismic Evaluation and Upgrade Criteria for Existing Welded Steel Moment-Resisting Frame Construction- These guidelines provide recommendations
for methods to evaluate the probable performance of steel frame structures in
future earthquakes and to retrofit these structures for improved performance.
Quality Assurance Guidelines for Moment-Resisting Steel FrameConstruction - These guidelines provide recommendations to engineers and
building officials for methods to ensure that steel frame structures are
constructed with adequate construction quality to perform as intended when
subjected to severe earthquake loading.
1.2 Intent
These guidelines are primarily intended for three different groups of potential users:
a) Engineers engaged in the design of new steel frame structures that may be subject to the
effects of earthquake ground shaking.
b) Regulators and building departments responsible for control of the design and
construction of structures in regions subject to the effects of earthquake ground shaking.
c) Organizations engaged in the development of building codes and standards for
regulation of the design and construction of steel frame structures that may be subject to
the effects of earthquake ground shaking.
The fundamental goal of the information presented in these guidelines is to help identify and
reduce the risks associated with the earthquake-performance of moment-resisting steel frame
structures. The information presented here primarily addresses the issue of beam-to-column
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WORKING DRAFT - This document has been produced by the SAC Joint Venture for the purposes of preliminary
review and coordination between members of the project team. Information presented is known to be incomplete
and in some cases erroneous. This document should not be used for attribution, nor as the basis for engineering
decisions
1-2 02/02/99
connection integrity under the severe inelastic demands that can be produced by building response
to strong ground motion. Users are referred to the applicable provisions of the locally prevailing
building code for information with regard to other aspects of building construction and earthquake
damage control.
1.3 Background
Following the January 17, 1994 Northridge, California Earthquake, a number of steel buildings
with welded steel moment-resisting frames (WSMF) were found to have experienced beam-to-
column connection fractures. The damaged structures cover a wide range of heights ranging from
one story to 26 stories; and a wide range of ages spanning from buildings as old as 30 years of age
to structures just being erected at the time of the earthquake. The damaged structures were spread
over a large geographical area, including sites that experienced only moderate levels of ground
shaking. Although relatively few such buildings were located on sites that experienced the
strongest ground shaking, damage to buildings located on such sites was extensive. Discovery of
unanticipated brittle fractures of framing connections, often with little associated architectural
damage to the buildings, was alarming. The discovery also caused some concern that similar, but
undiscovered damage may have occurred in other buildings affected by past earthquakes. Later
investigations actually confirmed such damage in buildings affected by the 1992 Landers Big Bear
and 1989 Loma Prieta earthquakes.
WSMF construction is commonly used throughout the United States and the world, particularly
for mid- and high-rise construction. Prior to the Northridge earthquake, this type of construction
was commonly considered to be very ductile and essentially invulnerable to damage that would
significantly degrade structural capacity, due to the fact that severe damage to such structures had
rarely been reported in past earthquakes and there was no record of earthquake-induced collapse of
such buildings. The discovery of brittle fracture damage in a number of buildings affected by the
Northridge Earthquake called for re-examination of this premise. In general, WSMF buildings in
the Northridge Earthquake met the basic intent of the building codes, to protect life safety.
However, the structures did not behave as anticipated and significant economic losses occurred as a
result of the connection damage. These losses included direct costs associated with the
investigation and repair of this damage as well as indirect losses relating to the temporary, and in
some cases, long term loss of use of space within damaged structures.
WSMF buildings are designed to resist earthquake ground shaking, based on the assumption
that they are capable of extensive yielding and plastic deformation, without loss of strength. The
intended plastic deformation consists of plastic rotations developing within the beams, at theirconnections to the columns, and is theoretically capable of resulting in benign dissipation of the
earthquake energy delivered to the building. Damage is expected to consist of moderate yielding
and localized buckling of the steel elements, not brittle fractures. Based on this presumed behavior,
building codes permit WSMF structures to be designed with a fraction of the strength that would be
required to respond to design level earthquake ground shaking in an elastic manner.
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WORKING DRAFT - This document has been produced by the SAC Joint Venture for the purposes of preliminary
review and coordination between members of the project team. Information presented is known to be incomplete
and in some cases erroneous. This document should not be used for attribution, nor as the basis for engineering
decisions
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Figure 1-2 - Fractures of Beam to Column Joints
a. Fractures through Column Flange b. Fracture Progresses into Column Web
Figure 1-3 - Column Fractures
Once such fractures have occurred, the beam - column connection has experienced a significant
loss of flexural rigidity and strength to resist loads that tend to open the crack. Residual flexural
strength and rigidity must be developed through a couple consisting of forces transmitted through
the remaining top flange connection and the web bolts. However, in providing this residual
strength and stiffness, the bolted web connections can themselves be subject to failures, consisting
of fracturing of the welds of the shear plate to the column, fracturing of supplemental welds to the
beam web or fracturing through the weak section of shear plate aligning with the bolt holes (Figure
1-4).
Figure 1-4 - Vertical Fracture through Beam Shear Plate Connection
Despite the obvious local strength impairment resulting from these fractures, many damaged
buildings did not display overt signs of structural damage, such as permanent drifts, or damage to
architectural elements, making reliable post-earthquake damage evaluations difficult. Until news of
the discovery of connection fractures in some buildings began to spread through the engineering
community, it was relatively common for engineers to perform cursory post-earthquake evaluations
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WORKING DRAFT - This document has been produced by the SAC Joint Venture for the purposes of internal
review and coordination between members of the project team. Information presented is known to be incomplete
and in some cases erroneous. This document should not be used for attribution, nor as the basis for engineering
decisions
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of WSMF buildings and declare that they were undamaged. Unless a building exhibits overt signs
of damage, such as visible permanent inter-story-drifts, in order to reliably determine if a building
has sustained connection damage it is often necessary to remove architectural finishes andfireproofing and perform detailed inspections of the connections. Even if no damage is found, this
is a costly process. Repair of damaged connections is even more costly. At least one WSMF
buildings sustained so much connection damage that it was deemed more practical to demolish the
structure rather than to repair it.
In response to concerns raised by this damage, the Federal Emergency Management Agency
(FEMA) entered into a cooperative agreement with the SAC Joint Venture to perform problem-
focused study of the seismic performance of welded steel moment connections and to develop
recommendations for professional practice. Specifically, these recommendations were intended
to address the inspection of earthquake affected buildings to determine if they had sustained
significant damage; the repair of damaged buildings; the upgrade of existing buildings toimprove their probable future performance; and the design of new structures to provide reliable
seismic performance.
During the first half of 1995, an intensive program of research was conducted to more
definitively explore the pertinent issues. This research included literature surveys, data collection
on affected structures, statistical evaluation of the collected data, analytical studies of damaged
and undamaged buildings and laboratory testing of a series of full-scale beam-column assemblies
representing typical pre-Northridge design and construction practice as well as various repair,
upgrade and alternative design details. The findings of these tasks (SAC 1995c, SAC 1995d,
SAC 1995e, SAC 1995f, SAC 1995g, SAC 1996) formed the basis for the development of
FEMA 267 -Interim Guidelines: Evaluation, Repair, Modification, and Design of Welded SteelMoment Frame Structures(SAC, 1995b), which was published in August, 1995. FEMA 267
provided the first definitive, albeit interim, recommendations for practice, following the
discovery of connection damage in the Northridge earthquake.
In the time since the publication of FEMA-267, SAC has continued to perform problem-
focused study of the performance of moment resisting steel frames and connections of various
configurations. This work has included detailed analytical evaluations of buildings and
connections, parametric studies into the effects on connection performance of connection
configuration, base and weld metal strength, toughness and ductility, as well as additional large
scale testing of connection assemblies. As a result of these studies, as well as independent
research conducted by others, it is now known that a large number of factors contributed to thedamage sustained by steel frame buildings in the Northridge earthquake. These included:
design practice that favored the use of relatively few frame bays to resist lateralseismic demands, resulting in much larger member and connection geometries than
had previously been tested;
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WORKING DRAFT - This document has been produced by the SAC Joint Venture for the purposes of internal
review and coordination between members of the project team. Information presented is known to be incomplete
and in some cases erroneous. This document should not be used for attribution, nor as the basis for engineering
decisions
1-6
standard detailing practice which resulted in large inelastic demands at the beam tocolumn connections;
detailing practice that often resulted in large stress concentrations in the beam-columnconnection, as well as inherent stress risers and notches in zones of high stress;
the common use of welding procedures that resulted in deposition of low toughnessweld metal in the critical beam flange to column flange joints;
relatively poor levels of quality control and assurance in the construction process,resulting in welded joints that did not conform to the applicable quality standards;
excessively weak and flexible column panel zones that resulted in large secondary
stresses in the beam flange to column flange joints;
large increases in the material strength of rolled shape members relative to specifiedvalues;
1.4 Application
This publication supersedes the design recommendations for new construction contained in
FEMA-267,Interim Guidelines: Evaluation, Repair, Modification and Design of Welded Steel
Moment Frame Structures, and theInterim Guidelines Advisory, FEMA-267a. It is intended to
be used in coordination with and in supplement to the locally applicable building code and those
national standards referenced by the building code. Building codes are living documents and arerevised on a periodic basis. This document has been prepared based on the provisions contained
in the 1997 NEHRP Provisions, the 1997AISC Seismic Specification(AISC, 1997) and the 1996
AWS D1.1 Structural Welding Code - Steel, as it is anticipated that these documents will form the
basis for 2000 edition of the International Building Code. Users are cautioned to carefully
consider any differences between the aforementioned documents and those actually enforced by
the building department having jurisdiction for a specific project and to adjust the
recommendations contained in these guidelines, accordingly.
1.5 The SAC Joint Venture
SAC is a joint venture of the Structural Engineers Association of California (SEAOC), theApplied Technology Council (ATC), and California Universities for Research in Earthquake
Engineering (CUREe), formed specifically to address both immediate and long-term needs
related to solving the problem of the welded steel moment frame (WSMF) connection. SEAOC
is a professional organization comprised of more than 3,000 practicing structural engineers in
California. The volunteer efforts of SEAOCs members on various technical committees have
been instrumental in the development of the earthquake design provisions contained in the
Uniform Building Codeas well as theNEHRP Provisions. The Applied Technology Council is a
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WORKING DRAFT - This document has been produced by the SAC Joint Venture for the purposes of internal
review and coordination between members of the project team. Information presented is known to be incomplete
and in some cases erroneous. This document should not be used for attribution, nor as the basis for engineering
decisions
1-7
non-profit organization founded specifically to perform problem-focused research related to
structural engineering and to bridge the gap between civil engineering research and engineering
practice. It has developed a number of publications of national significance including ATC 3-06,which served as the basis for theNEHRP Provisions. CUREes eight institutional members are:
the University of California at Berkeley, the California Institute of Technology, the University of
California at Davis, the University of California at Irvine, the University of California at Los
Angeles, the University of California at San Diego, the University of Southern California, and
Stanford University. This collection of university earthquake research laboratory, library,
computer and faculty resources is the most extensive in the United States. The SAC Joint
Venture allows these three organizations to combine their extensive and unique resources,
augmented by subcontractor universities and organizations from around the nation, into an
integrated team of practitioners and researchers, uniquely qualified to solve problems in
earthquake engineering.
The SAC Joint Venture developed a two phase program to solve the problem posed by the
discovery of fractured steel moment connections following the Northridge Earthquake. Phase 1
of this program was intended to provide guidelines for the immediate post-Northridge problems
of identifying damage in affected buildings and repairing this damage. In addition, Phase 1
included dissemination of the available design information to the professional community. It
included convocation of a series of workshops and symposiums to define the problem;
development and publication of a series of Design Advisories (SAC-1994-1, SAC-1994-2, SAC-
1995); limited statistical data collection, analytical evaluation of buildings and laboratory
research; and the preparation of theInterim Guidelines: Evaluation, Repair, Modification and
Design of Welded Steel Moment Frame Structures, FEMA-267. The Phase 2 project was
comprised of a longer term program of research and investigation to more carefully define theconditions which lead to the premature connection fractures and to develop sound guidelines for
seismic design and detailing of improved or alternative moment resisting frame systems for new
construction, as well as reliable retrofitting concepts for existing undamaged WSMF structures.
Detailed summaries of the technical information that forms a basis for these guidelines are
published in a separate series of State-of-Art reports (SAC, 1999a), (SAC, 1999b), (SAC,
1999c), (SAC, 1999d), and (SAC, 1999a).
1.6 Sponsors
Funding for Phases I and II of the SAC Steel Program was principally provided by the Federal
Emergency Management Agency, with ten percent of the Phase I program funded by the State ofCalifornia, Office of Emergency Services. Substantial additional co-funding, in the form of
donated materials, services, and data has been provided by a number of individual consulting
engineers, inspectors, researchers, fabricators, materials suppliers and industry groups. Special
efforts have been made to maintain a liaison with the engineering profession, researchers, the steel
industry, fabricators, code writing organizations and model code groups, building officials,
insurance and risk-management groups and federal and state agencies active in earthquake hazard
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WORKING DRAFT - This document has been produced by the SAC Joint Venture for the purposes of internal
review and coordination between members of the project team. Information presented is known to be incomplete
and in some cases erroneous. This document should not be used for attribution, nor as the basis for engineering
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mitigation efforts. SAC wishes to acknowledge the support and participation of each of the above
groups, organizations and individuals.
1.7 Guidelines Overview
The following is an overview of the general contents of chapters contained in these
guidelines, and their intended use:
Chapter 2 - General Requirements. This chapter, together with Chapter 3, areintended to supplement the building code requirements for design of moment-
resisting steel frame structures. This chapter includes discussion of referenced codes
and standards; design performance objectives; selection of structural systems;
configuration of structural systems; and analysis of structural frames to obtain
response parameters (forces and deflections) used in the code design procedures. Italso includes discussion of an alternative, performance-based design approach that
can be used at the engineers option, to design for superior or more reliable
performance than is attained using the code based approach. Guidelines for
implementation of the performance-based approach are contained in Chapter 4.
Chapter 3 - Connection Qualification. Moment-resisting steel frames canincorporate a number of different types of beam-column connections. Based on
research conducted by the SAC Joint Venture, a number of connection details have
been pre-qualified for use with different structural systems. This chapter provides
information on the limits of this pre-qualification for various types of connections and
specific design and detailing recommendations for these pre-qualified connections. Italso includes performance data on these connections for use with the performance-
based design procedures of Chapter 4. In some cases it may be appropriate to use
connection details and designs which are different than the pre-qualified connections
contained in this Chapter, or to use one of the pre-qualified connection details outside
the range of its pre-qualification. This chapter provides guidelines for project-specific
qualification of a connection in such cases. It also includes reference to several
proprietary connection types that may be utilized under license agreement with
individual patent holders. When proprietary connections are used in a design,
qualification data for such connections should be obtained directly from the licenser.
Chapter 4 - Performance Evaluation- This chapter provides a performanceevaluation procedure that may be used in the performance-based design process. This
procedure allows the probability that a structure will exceed one of several
performance states to be estimated, together with a level of confidence on this
estimate. The guidelines of this chapter are intended to be optional and apply only to
the use of performance-based design approaches.
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Chapter 5 - Materials and Fracture Resistant Design- This chapter providesfundamental information on the basic properties of steel materials and the conditions
under which structural steel fabrications can be subjected to brittle fractures. A moredetailed treatment of this information may be found in the companion publication,
FEMA-XXX State of Art Report on Materials and Fracture.
Chapter 6- Structural Specifications- This chapter presents a guidelinespecification, in CSI format, that may be used as the basis for a structural steel
specification for moment-resisting steel frame construction. Note that this guideline
specification must be carefully coordinated with other sections of the project
specifications when implemented as part of the construction documents for a project.
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2. GENERAL REQUIREMENTS
2.1 Scope
This Chapter presents overall guidelines for the design of moment-resisting steel frames
(MRSF) for new buildings and structures. Guidelines are provided for three different MRSF
systems, each with different levels of inelastic deformation capability. Included herein are
guidelines on applicable codes and standards, recommended performance objectives, system
selection, system analysis, frame design, connection design, specifications, quality control and
assurance, and other structural systems.
2.2 Applicable Codes and Standards
MRSF systems should, as a minimum, be designed in accordance with the applicable
provisions of the prevailing building code and these Guidelines. The Guidelines are specificallywritten to be compatible with the 1997 NEHRP Provisions(FEMA 302). Where these
Guidelines are different than the prevailing code, these Guidelines should take precedence. The
following are the major references:
FEMA 302 NEHRP Recommended Provisions for Seismic Regulations for New
Buildings and Other Structures, 1997 Edition
AWS D1.1 Structural Welding Code, 1996 Edition
AISC Seismic Seismic Provisions for Structural Steel Buildings, April 15, 1997
AISC-LRFD Load and Resistance Factor Design Specifications for Structural Steel
Buildings
Commentary: The 1994 and 1997 Uniform Building Codes, as well as the 1997 AISC
Seismic Provisions (AISC), provide design requirements for MRSF structures, including
a requirement that connection designs be based on tests. The 1997 NEHRP
Recommended Provisions (NEHRP) adopt the 1997 AISC Seismic Provisions by
reference as the design provisions for seismic force resisting systems of structural steel.
The International Building Code (IBC), scheduled for publication in the year 2000, is
expected to be based generally on the NEHRP Provisions, and is expected to have design
requirements for steel structures primarily based on the AISC provisions. It is anticipatedthat by the time the IBC is published many of the recommendations of these guidelines
will be incorporated therein as modifications of the AISC or that the AISC will be
modified and incorporated by reference. These guidelines are written to be compatible
with the AISC and NEHRP Provisions and reference will be made to sections of those
documents where appropriate herein.
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2.3 Design Performance Objectives
Under the 1997NEHRP Provisions, each building and structure must be assigned to one of
three Seismic Use Groups (SUGs). Buildings are assigned to the SUGs based on their intended
occupancy and use. Most commercial, residential and industrial structures are assigned toSeismic Use Group I. Buildings occupied by large numbers of persons, or by persons with
limited mobility, or house large quantities of potentially hazardous materials are assigned to
Seismic Use Group II. Buildings that are essential to post-earthquake disaster response and
recovery operations are assigned to Seismic Use Group III. Buildings in SUG II and III are
respectively intended to provide better performance, as a class, than buildings in SUG-I. As
indicated in theNEHRP Provisions Commentary,each SUG is intended to provide the
performance indicated in Figure 2-1.
OperationalImmediateOccupancy
LifeSafe
NearCollapse
FrequentEarthquakes(50% - 50 years)
DesignEarthquake(2/3 of MCE)
MaximumConsideredEarthquake(2% - 50 years)
PerformanceforG
oupIBuildings
PerformanceforG
oupIIIBuildings
PerformanceforG
oupIIBuildings
Building Performance Levels
GroundMotionLevels
Figure 2-1 - NEHRP Seismic Use Groups and Performance
The NEHRP Provisions attempt to obtain these various performance characteristics through
regulation of design force levels, limiting lateral drift values, system selection, and detailing
requirements, based on the SUG, the seismicity of the region containing the building site and the
effect of site specific geologic conditions. Structures should, as a minimum, be assigned to anappropriate SUG, in accordance with the building code, and be designed in accordance with the
applicable requirements.
Although theNEHRP Provisions Commentaryimplies that buildings designed in accordance
with the requirements for the various SUGs are capable of providing the alternative performance
capabilities indicated in Figure 2-1, theNEHRP Provisionsdo not contain direct methods to
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evaluate and verify the actual performance capability of structures, nor do they provide a direct
means to design for performance characteristics other than those implied for each of the SUGs.
It is believed, based on observation of the performance of modern, code conforming construction
in recent earthquakes, that theNEHRP Provisionsprovide reasonable reliability with regard to
attaining Life Safe performance for SUG-1 structures subjected to rare events, as indicated in
Figure 2-1. However, the reliability of theNEHRP Provisionswith regard to attainment of other
performance objectives for SUG-1 structures, or for reliably attaining any of the performance
objectives for the other SUGs seems less certain and has never been quantified or verified.
Chapters 2 and 3 of these Guidelines, present code-based design recommendations for MRSF
structures. All buildings should, as a minimum, be designed in accordance with these
recommendations. For buildings in which it is desired to attain other performance than implied
by the code, or for which it is desired to have greater confidence that the building will actually be
capable of attaining the desired performance, the Guidelines of Chapters 4 and 5 may be applied.
Commentary: The NEHRP provisions include three types of moment resisting steelframes (MRSFs) all of which are incorporated in these guidelines. The three types are:
Special Moment Frames (SMF), Intermediate Moment Frames (IMF), and Ordinary
Moment Frames (OMF). These systems are described in more detail in the section on
system selection. In the NEHRP provisions, a unique R value is assigned to each of these
systems, as are height limitations and other restrictions on use. Regardless of the system
selected, the NEHRP provisions imply that structures designed to meet the requirements
therein will be capable of meeting the Collapse Prevention performance level for a
Maximum Considered Earthquake (MCE) ground motion level and will provide Life Safe
performance for the Design Basis Earthquake (DBE) ground motion that has a severity of
2/3 of the severity of the MCE ground motion. This 2/3 factor is based on the assumption
by the provisions that the Life Safety performance on which earlier editions of the
provisions were based inherently provided a minimum margin of 1.5 against collapse.
Except for sites located within a few kilometers of known active faults, the MCE ground
motion is represented by a ground shaking response that has a 2% probability of
exceedance in 50 years (2500 year mean return period). For sites that are close to
known active faults, the MCE ground motion is taken either as this 2%/50 year spectrum,
or as a spectrum that is 150% of that determined from a median estimate of the ground
motion resulting from a characteristic event on a known active fault, whichever is less.
This is compatible with the approach taken by the 1997 UBC for the definition of design
ground motion on sites near major active faults.
The UBC and NEHRP provisions both define classes of structures for which
performance superior to that described above is mandated. Additionally, individual
building owners may desire a higher level of performance than that described. The UBC
attempts to achieve higher performance through specification of an occupancy
importance factor which increases the design force level; the NEHRP provisions attempt
to improve performance through use of both an occupancy importance factor and of more
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restrictive drift limits. The combination of increased design forces and more restrictive
drift limitations leads to substantially greater strength in systems such as SMFs, the
design of which is governed by drift.
The NEHRP R factors, drift limits, and height limitations, as well as the inelasticrotation capability requirements corresponding to the R value for each moment frame
type (SMF, IMF, or OMF), are based more on historical precedent and judgment than
they are on analytical demonstration. In the research program on which these guidelines
are based, an extensive series of nonlinear analytical investigations has been conducted
to determine the drift demands on structures designed in accordance with the current
code when subjected to different ground motions. The results of these investigations have
led to these Guidelines recommending modifications to some of the NEHRP and AISC
design provisions where there was concern that the intended performance would not be
achieved.
It should be recognized that application of the modifications in these Guidelines,while considered necessary to achieve the indicated performance for moment frames,
may make such systems perform better than some other systems which may not have had
as significant an analytical base for their provisions. In other words, some other systems
included in the NEHRP provisions, both of steel and of other materials, have provisions
which may provide a lower level of assurance that the resulting structures will meet the
intended performance level. It is also worthy of note that the three classes of steel MRSF
systems contained in the NEHRP Provisions are themselves not capable of providing
uniform performance. OMF structures will typically be stronger than either IMF or SMF
systems, but can have much poorer inelastic response characteristics. The result of this
is that OMF structures should be able to resist the onset of damage at somewhat stronger
levels of ground shaking than is the case for IMF or SMF structures. However, as
ground motion intensity increases beyond the damage threshold for each of these
structural types, it would be anticipated that OMF structures would present a much
greater risk of collapse than would IMF structures, which in turn, would present a more
significant risk of collapse then SMF structures. For these reasons, the NEHRP
Provisions place limitations on the applicability of these various structural systems
depending on the height of a structure, and the seismic hazard at the site.
The reader is referred to Chapter 4 for more detailed discussion of recommended
performance levels and their implications.
2.4 System Selection
2.4.1 Configuration and Load Path
Every structure should be provided with a complete load path, capable of transmitting inertial
forces from the foundations to the locations of mass throughout the structure. For moment-
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resisting frame structures, the load path includes the foundations, the moment-resisting frames,
floor and roof diaphragms and the various collector elements that interconnect these system
components.
To the extent possible, the structural system should have a regular configuration withoutsignificant discontinuities in stiffness or strength and with the rigidity of the structural system
distributed uniformly around the center of mass.
2.4.2 Selection of Moment Frame Type
The NEHRP Provisions define three types of MRSFs: Special Moment Frames (SMF),
Intermediate Moment Frames (IMF), and Ordinary Moment Frames (OMF). Detailing and
configuration requirements are specified for each of these three frame types to provide different
levels of reliable ductility (inelastic rotation capability) and consequent drift angle capacity,
varying from highest in SMFs to lowest in OMFs. The selection of moment frame type should
be governed by the prevailing code and by the project conditions. Consideration should be givento using the more ductile systems.
Commentary: Although the NEHRP provisions, as modified by these guidelines, are
intended to provide the same level of seismic performance for all three of the frame types
given the conformance of all actual conditions to the limits of the assumed conditions, it
is recognized that variations will occur in ground motions as well as in other conditions
of design, and it is judged that higher ductility (higher inelastic rotation capability) is
likely to provide a greater margin of safety if conditions beyond those anticipated should
be experienced. For this reason, the NEHRP Provisions place limitations on the height
and or relative importance or seismic exposure (Seismic Design Category) for structures
which employ OMFs and IMFs as compared to those with SMFs. Because of theaforementioned higher margin, it is recommended that designers and owners consider
the cost versus benefit of using systems with higher relative ductility whenever seismic
forces govern the design.
The NEHRP Provisions and AISC Seismic use inelastic rotation demand as the
primary design parameter for judging frame and connection performance, as did FEMA-
267. SAC has decided to use interstory drift demand as the design parameter, because
this parameter is analytically stable, will provide good correlation with performance,
and is relatively simple to predict using common analysis methods.
2.4.3 Connection Type
Either Fully Restrained (FR) or Partially Restrained (PR) connections are permitted for all
three MRSF systems in the 1997 NEHRP Provisions. The provisions require that the
connections meet minimum strength requirements and be demonstrated by test to be capable of
providing minimum levels of rotational capacity. The provisions also require that the additional
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drift due to connection flexibility (for PR connections) be accounted for in the design, including
P-Delta effects. In Chapter 3, design procedures are provided for several types of pre-qualified
FR and PR connections, together with limitations on the applicability of the pre-qualification.
Guidelines for analysis of frames comprising these connections are given in Chapter 4. Designs
employing connections that are not pre-qualified under these Guidelines, should be demonstrated
by test to be capable of providing the minimum levels of drift angle capacity required for the
system being used.
Commentary: In many areas of the United States, modern era moment frames have been
designed as type FR almost exclusively. On the other hand, in most areas, there are some
older mid to highrise buildings designed with what would now be referred to as PR
connections, and some engineers have a current practice of using PR connections in low
to moderate seismic zones. Accordingly, research was undertaken as part of this project
to permit development of rational guidelines for the design and analysis of such systems
and to provide connection design guidelines which do not require project connection
testing.
2.4.4 Redundancy
The 1997 NEHRP Provisionsinclude a redundancy factor, , with values between 1.0 and1.5, which is applied as a load factor on calculated earthquake forces for structures categorized
as Seismic Design Category (SDC) D, E, or F. Less redundant systems (frames with fewer
participating beams and columns) will have higher values of the redundancy factor and therefore
will require higher design forces to compensate for their lack of redundancy. Additionally, since
the design of MRSFs is typically governed by considerations of drift control, rather than
strength, MRSFs are required to be configured to qualify for a redundancy factor 1.25 or less (or
1.1 for SDCs E and F).
Designers should as a minimum, provide the level of redundancy required by the code.
Whenever it is practical to do so, as many moment resisting connections as is reasonable should
be incorporated into the moment frame.
Commentary: Redundancy has obvious advantages for structures subjected to random
brittle fractures or failures resulting from occasional poor construction quality or an
imbalance in material strengths of the various connected elements. If brittle connection
fractures occur, it can be assumed that fractures, will not occur in all connections at the
same time. Thus, more ductile connections will be available to dissipate earthquake
energy, after a given number of fractures occur, in more redundant buildings. Cornell
and Luco (Ref. ) have done a limited study on this issue, which was not very conclusive.
The effect of redundancy was not very strong, even when a rotation capacity benefit was
given to the connections of the shallower beams of the more redundant structure.
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Another important advantage of providing redundant framing systems is that the use of a
larger number of frames to resist lateral forces often permits the size of the framing
elements to be reduced. Laboratory research has shown that connection ductility
generally decreases as the size of the framing increases.
2.5 Structural Materials
2.5.1 Material Specifications
Structural steel should conform to the specifications and grades permitted by the building
code, unless a project-specific qualification testing program is performed to demonstrate
acceptable performance of alternative materials.
2.5.2 Material Strength Properties
The AISC Seismic Provisions (Ref. ) state:
When required by these provisions, the required strength of a connection or related
member shall be determined from the Expected Yield Strength Fyeof the connected
member, where
Fye= RyFy (2-1)
The Provisions state further that Ryshall be taken as 1.5 for ASTM A36 and 1.3 for A572
Grade 42. For rolled shapes and bars of other grades of steel and for plates, Ryshall be taken as
1.1. Other values of Ryare permitted to be used if the value of Fyeis determined by testing that is
conducted in accordance with the requirements for the specified grade of steel.
For normal design purposes the AISC requirements should be followed as a minimum.
Where a higher than normal reliability is desired, the designer should consider the variability of
the properties and apply appropriate coefficients of variation.
Commentary: The SAC studies of rolled sections of Grade 50 steel indicates that the 1.1
value for Ryis a good representation of the mean value of yield strength. The study also
developed statistics on the sectional properties of current rolled shapes. The statistics are
given in the table below:
Statistic F m/Fy Area Zx Zy
Mean 1.09 0.990 0.987 0.984
COV 0.080 0.018 0.019 0.025
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In the relationship Fm/Fy, Fmrepresents the measured dynamic yield strength and Fyis,
as usual, the specified minimum yield stress , or in this case 50 ksi.
We can see that in the mean, the expected yield strength, Fye, is reasonably assumed to be
1.1Fy. If a higher level of reliability is desired, values that account for the statisticalvariance may be used. The yield overstrength is somewhat offset by the fact that in the
mean the cross sectional properties are lower than the nominal. The mean value of the
product of the yield strength statistic with the cross sectional properties can be estimated
as the product of the means of the two values. The variance of the product can be
estimated as the sum of the squares of the variance of each parameter. The estimated
means and variances and the mean +/-1 and 2 times the variance are shown in the table
below:
Parameter Mean Variance Mean -1
Variance
Mean+ 1
Variance
Mean -2
Variance
Mean+ 2
Variance
Squash Load
Py=FyAgross
1.040 0.082 0.958 1.122 0.876 1.204
Plastic Moment
Mpx= FyZx
1.039 0.082 0.957 1.121 0.874 1.203
Plastic Moment
Mpy= FyZy
1.037 0.084 0.953 1.121 0.869 1.205
It can be seen from the table that the Ry value of 1.1 for Grade 50 steel will give
reasonable conformance with Mean + 1 Variance values. A reasonable estimate of theupper bound of the beam strength is 1.2 times the nominal value of the plastic moment.
The designer may wish to use this value when seeking a higher than normal level of
reliability for the associated connections.
Similar studies for the other grades of steel have not been performed as part of the SAC
program. It is recommended that in the absence of specifically tested values for beam
steels being used in the project, that the values for Grade 50 be used, unless steels with
higher specified minimum yield stresses are being used, in which case, special
qualification testing would be required.
2.6 Structural Analysis
An analysis should be performed for each structure to determine the distribution of forces and
deformations under code specified ground motion and/or loading criteria. The analysis should
conform, as a minimum, to the code specified criteria for equivalent lateral force (ELF), Modal
Response Spectrum (MRS) or Response-history analysis, as applicable.
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Chapter 4 provides guidance on analysis methods applicable to performance evaluation of
WSMF structures.
Commentary: Seismic design forces for low to mid-rise buildings without major
irregularities have traditionally been determined primarily by using the simpleequivalent static method prescribed by the codes. Such methods are incorporated in
the 1997 NEHRP Provisions and are permitted to be used for structures designated as
regular up to 240 feet in height.Buildings which are over5 stories or 65 feet in height
and have certain vertical irregularities, and all buildings over 240 feet in height, require
use of dynamic (modal or time history) analysis. The use of elastic or inelastic response
history, or of non-linear static analysis is also permitted, though few guidelines are
provided in the code for how to apply such analysis. Projects incorporating non-linear
response-history analysis should be conducted in accordance with the performance
evaluation provisions of Chapter 4.
2.7 Mathematical Modeling
2.7.1 Basic assumptions
In general, a steel frame building should be modeled, analyzed and designed as a three-
dimensional assembly of elements and components. Although two-dimensional models may
provide adequate design information for regular, symmetric structures and structures with
flexible diaphragms, three-dimensional mathematical models should be used for analysis and
design of buildings with plan irregularity as defined by theNEHRP Provisions. Two-
dimensional modeling, analysis, and design of buildings with stiff or rigid diaphragms is
acceptable if torsional effects are either sufficiently small to be ignored, or indirectly captured.
Vertical lines of framing in buildings with flexible diaphragms may be individually modeled,
analyzed and designed as two-dimensional assemblies of components and elements, or a three-
dimensional model may be used with the diaphragms modeled as flexible elements.
Explicit modeling of a connection is required for nonlinear procedures if the connection is
weaker than the connected components, and/or the flexibility of the connection results in a
significant increase in the relative deformation between connected components.
2.7.2 Frame configuration
The analytical model should accurately account for the stiffness effects of frame connections.Element and component stiffness properties and strength estimates for both linear and nonlinear
procedures can be determined from information given in Chapter 3 for pre-qualified connections.
Guidelines for modeling structural components are given in Chapter 4.
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A xavg
=
max
.12
2
(2-2)
where:
max = Maximum displacement at any point of the diaphragm at level x
avg = Average of displacements at the extreme points of the diaphragm at level x
If the ratio, ,of (1) the maximum displacement at any point on any floor diaphragm(including torsional amplification), to (2) the average displacement, calculated by rational
analysis methods, exceeds 1.50, three-dimensional models that account for the spatial
distribution of mass and stiffness should be used for analysis and design. Subject to this
limitation, the effects of torsion may be indirectly captured for analysis of two-dimensional
models as follows:
a. For the Linear Static Procedure (LSP) and the Linear Dynamic Procedure (LDP), the
design forces and displacements should be increased by multiplying by the maximum
value of calculated for the building.
b. For the Nonlinear Static Procedure (NSP), the target displacement should be increased by
multiplying by the maximum value of calculated for the building.
c. For the Nonlinear Dynamic Procedure (NDP), the amplitude of the ground acceleration
record should be increased by multiplying by the maximum value of calculated for thebuilding.
2.7.4 Foundation modeling
Foundations should be modeled considering the relative stiffness of the foundation systems
and the rigidity of attachment of the structure to the foundation. Soil-structure interaction may
be modeled as permitted by the building code. Assumptions with regard to the extent of fixity
against rotation provided at the base of columns should realistically account for the relative
rigidities of the frame and foundation system, including soil compliance effects, and the detailing
of the column base connections.
Commentary: Most moment-resisting steel frames can be adequately modeled byassuming that the foundation provides rigid support for vertical loads. However, the
flexibility of foundation systems (and the attachment of columns to those systems) can
significantly alter the flexural stiffness at the base of the frame.
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2.7.5 Diaphragms
Floor diaphragms transfer earthquake-induced inertial forces to vertical elements of the
seismic framing system. Roof diaphragms are considered to be floor diaphragms. Connections
between floor diaphragms and vertical seismic framing elements must have sufficient strength totransfer the maximum calculated diaphragm shear forces to the vertical framing elements.
Requirements for design and detailing of diaphragm components are given in theNEHRP
Provisions.
Floor diaphragms should be classified as either flexible, stiff, or rigid in accordance with the
NEHRP Provisions. Most floor slabs with concrete fill over metal deck may be considered to be
rigid diaphragms. Floors or roofs with plywood diaphragms should be considered flexible. The
flexibility of unfilled metal deck, and concrete slab diaphragms with large openings should be
considered in the analytical model.
Mathematical models of buildings with stiff or flexible diaphragms should be developedconsidering the effects of diaphragm flexibility. For buildings with flexible diaphragms at each
floor level, the vertical lines of seismic framing may be designed independently, with seismic
masses assigned on the basis of tributary area.
2.7.6 P-Delta effects
Two types of P-(second-order) effects are addressed in the Guidelines: (1) static P-and(2) dynamic P-.
Commentary: Structure P-delta effect, caused by gravity loads acting on the displaced
configuration of the structure, may be critical in the seismic performance of SMRF structures,which are usually rather flexible and may be subjected to relatively large lateral displacements.
Structure P-delta effect has consequences from the perspectives of statics and dynamics. In a
static sense this effect can be visualized as an additional lateral loading that causes an increase
in member forces and lateral deflections, reduces the lateral resistance of the structure, and may
cause a negative slope of the lateral load - displacement relationship at large displacements.
This response is obtained from an accurate distributed plasticity analysis of the frame. From a
static perspective the maximum lateral load that can be applied to the structure is a critical
quantity since this load cannot be maintained as displacements increase, and a sidesway
collapse is imminent. From a dynamic perspective this maximum load is not a critical quantity
since seismic "loading" implies energy input, and stability is maintained as long as energy canbe dissipated within the structural system. In concept, collapse will not occur unless the lateral
forces due to P-delta effects exceed the available restoring forces. These restoring forces
include the internal forces generated in the structure, as a result of its displaced shape, as well
as inertial forces induced by continued shaking and response of the structure to this shaking.
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An accurate determination of the inelastic response that includes all aspects of member and
structure P-delta effects is possible only through a distributed plasticity finite element analysis.
To be reliable, this analysis should also incorporate local and flexural-torsional buckling effects.
The response determination under cyclic loading is even more complex, particularly if strength
and/or stiffness deterioration have to be considered. If local and flexural-torsional buckling
problems are avoided, if member P-delta effects and out-of-plane buckling are not important
issues, and if strength and stiffness deterioration are prevented, then a second order
concentrated plasticity (plastic hinge) analysis should be adequate for an assessment of P-delta
effects. The following discussion is based on these assumptions.
For structures of more than one story (MDOF systems), P-delta becomes a problem that
depends on the properties of individual stories. P-delta effects reduce the effective resistance of
each story by an amount approximately equal to Pii/hi, where Pi, i, and hi are the sum of
vertical forces, interstory deflection, and height, respectively, of story i. Thus, large P-delta
effects, which may lead to an effective negative story stiffness at large displacements, are caused
by either large vertical story forces (lower stories) or large story drifts.
Work by Krawinkler (ref) examined the base shear versus roof drift angle (roof displacement
over structure height) response of a three story structure, using a basic centerline model (Model
M1, discussed later). Responses with and without P-delta effects were examined. When P-delta
is ignored, the response maintains a hardening stiffness even at very large drifts (3% strain
hardening is assumed in the element models). When P-delta is included, the structural response
changes radically, exhibiting only a short strength plateau followed by a rapid decrease in
resistance (negative stiffness) and a complete loss of lateral resistance at the relatively small
global drift of 4%. This global force- displacement behavior is alarming, but it does not provide
much insight into P-delta since this phenomenon is controlled by story properties.
The negative post-mechanism stiffness of the bottom five stories of a 9 story building
examined by Krawinkler (ref) is about the same and is approximately equal to -6% of the elastic
story stiffness. This negative stiffness arises because the P/h "shear" counteracts the 3% strain
hardening that would exist without P-delta. This research implies that the structure would
collapse in an earthquake because of complete loss in vertical load resistance if in any of the five
bottom stories the drift approaches 16%. A similar conclusion cannot be drawn for the upper
stories which show a very small drift at zero lateral resistance. These stories recover effective
stiffness as the structure is being pushed to larger displacements because of their smaller P-delta
effect. Thus, as the displacements are being increased in the negative stiffness range, the lower
stories drift at a much higher rate and contribute more and more to the total structure drift.Deflected shapes of the structure as it is pushed under the given load pattern to the maximum
global drift of 0.04 radians constitutes an instability condition at which the structure is at
incipient collapse under gravity loads alone because of P-delta effects.
The amplification of drift in the lower stories and the de-amplification in the upper stories,
as the structure is being pushed to larger displacements, shows ratios of story drift angle to roof
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drift angle, plotted against roof drift angle, for all 20 stories. These curves show that in the
elastic range all story drifts are about equal, but that great differences in drifts exist in the
inelastic range. The rapid increase in drift in stories 1 to 5 is evident. At very large drifts the
contributions of the upper stories to the deflection become negligible.
It needs to be noted that the contributions of the individual stories to drift depend on the load
pattern selected in the pushover analysis. In this study the NEHRP94 (FEMA-222A, 1994)
design load pattern with k = 2.0 is selected. Drastic changes in the presented results are not
expected if different load patterns would have been chosen. From a design perspective it is
critical to understand the behavior characteristics from the pushover analysis in order to
evaluate the importance of P-delta.
For steel moment frame structures in which member buckling is prevented, incremental
sidesway collapse due to structure P-delta is the predominant global collapse mode. The P-delta
problem is not adequately addressed in present codes. The utilization of an elastic stability
coefficient , such as the one used in the NEHRP94 provisions [= P/(Vh)], provides little
protection against the occurrence of a negative post-mechanism stiffness and against excessive
drifting of the seismic response.
Because of the potential importance of P-delta effects on the seismic response of flexible
SMRF structures it is imperative to consider these effects when performing a nonlinear analysis.
If two-dimensional analytical models are used it is customary to represent only moment resisting
frames and ignore the presence of frames with simple (shear) connections. However, what
cannot be ignored is the fact that the moment resisting frames have to resist the P-delta effects
caused by vertical loads tributary to the frames with simple connections. One simple way of
including these effects is to add an elastic "P-delta column" to the 2-D model, which is loaded
with all the vertical loads tributary to the simple frames. This column should have negligible
bending stiffness so it can take on the deflected shape of the moment frames without attracting
bending moments.
2.7.6.1 Static P-Effects
The structure should be investigated to ensure that lateral drifts induced by earthquake
response do not result in a condition of instability under gravity loads. At each story, the quantity
ishould be calculated for each direction of response, as follows:
i i ii i
P
V h= (23)
where:
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Pi = Portion of the total weight of the structure including dead, permanent live, and
25% of transient live loads acting on the columns and bearing walls within story
level i.
Vi = Total calculated lateral shear force in the direction under consideration at story idue to earthquake response, assuming that the structure remains elastic.
hi = Height of story i, which may be taken as the distance between the centerline of
floor framing at each of the levels above and below, the distance between the top
of floor slabs at each of the levels above and below, or similar common points of
reference.
i = Lateral drift in story i, in the direction under consideration, at its center of rigidity,using the same units as for measuring hi.
In any story in which iis less than or equal to 0.1, the structure need not be investigatedfurther for stability concerns. When the quantity iin a story exceeds 0.1, the analysis of thestructure should consider P-effects. When the value of iexceeds 0.33, the structure should beconsidered potentially unstable and the design modified to reduce the computed lateral
deflections in the story.
This process is iterative. For linear procedures, ishould be increased by 1/(1-)forevaluation of the stability coefficient.
Commentary: For a bilinear SDOF system with mass m and height h the dimensionless
parameter = mg/(Kh) can be used as indicator of the severity of P- effects. The elastic
stiffness K is reduced to (1- )K, and the post-elastic stiffness K is reduced to ( - )K. In this
formulation is the strain hardening ratio of the system without P-delta effect, and - is the
strain "hardening" ratio with P-delta effects, which is denoted here as the effective strain
"hardening" ratio . If > , then becomes negative.
For nonlinear procedures, second-order effects should be considered directly in the analysis;
the geometric stiffness of all elements and components subjected to axial forces should be
included in the mathematical model.
2.7.6.2Dynamic P-EffectsDynamic P-effects may increase component actions and deformations, and story drifts.
Second-order effects should be considered directly for nonlinear procedures; the geometric
stiffness of all elements and components subjected to axial forces should be included in the
mathematical model.
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Commentary: From a dynamic perspective the structure P-delta effect may lead to a
significant amplification in displacement response if is negative and the displacement demands
are high enough to enter the range of negative lateral stiffness. The dynamic response of an
SDOF system whose hysteretic behavior is bilinear but includes P-delta effects can lead to a
negative post-elastic stiffness K = -0.03K. The presence of the negative stiffness leads to
drifting (ratcheting) of the displacement response, which brings the SDOF system close to
collapse. Research using a suite of time histories (Ref) mean values of the displacement
amplification factor (displacement for = -0.03 over displacement for = 0.0) for different
strength reduction factors R (R = elastic strength demand over yield strength) and a period
range from 0 to 5.0 sec. were developed. It is evident that the displacement amplification
depends strongly on the yield strength (R-factor) and the period of the SDOF system.
Particularly for short period systems with low yield strength the amplification can be
substantial. The diagrams are terminated at the last period of stability, i.e., for shorter periods
at least one record did lead to a complete loss of lateral resistance.
2.7.7 Multidirectional excitation effects
Buildings should be designed for seismic forces in any horizontal direction. For regular
buildings, seismic displacements and forces may be assumed to act nonconcurrently in the
direction of each principal axis of a building. For buildings with plan irregularity and buildings
in which one or more components form part of two or more intersecting elements,
multidirectional excitation effects should be considered. Multidirectional effects on components
should include both torsional and translational effects.
The requirement that multidirectional (orthogonal) excitation effects be considered may be
satisfied by designing elements or components for the forces and deformations associated with100% of the seismic displacements in one horizontal direction plus the forces associated with
30% of the seismic displacements in the perpendicular horizontal direction. Alternatively, it is
acceptable to use SRSS to combine multidirectional effects where appropriate.
The effects of vertical excitation on horizontal cantilevers and prestressed elements should be
considered by static or dynamic response methods. Vertical earthquake should be considered by
static or dynamic response methods. Vertical earthquake shaking may be characterized by a
spectrum with ordinates equal to 67% of those of the horizontal spectrum unless alternative
vertical response spectra are developed using site-specific analysis.
2.7.8 Verification of analysis assumptions
Each component should be evaluated to determine that assumed locations of inelastic
deformations are consistent with strength and equilibrium requirements at all locations along the
component length. Further, each component should be evaluated by rational analysis for
adequate post-earthquake residual gravity load capacity, considering reduction of stiffness caused
by earthquake damage to the structure.
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Where moments in horizontally-spanning primary components, due to the gravity loads,
exceed 50% of the expected moment strength at any location, the possibility for inelastic flexural
action at locations other than components ends should be specifically investigated by comparing
flexural actions with expected component strengths, and the post-earthquake gravity load
capacity should be investigated. Formation of flexural plastic hinges away from component ends
should not be permitted unless it is explicitly accounted for in modeling and analysis.
2.8 Frame Design
The following provisions supplement the parallel provisions contained in the building code.
2.8.1 Strength of Beams and Columns
The AISC Seismic Provisions (Equation (9-3)) includes relationships which must be satisfied
to provide for a nominal condition of columns being stronger than the beams connected to them
(for SMFs and IMFs). The AISC equation uses the expected